Method for producing a ceramic substrate

ABSTRACT

A method is disclosed for producing a ceramic substrate made of base that includes a stack of layers. Each layer in the stack includes a non-sintered ceramic material and a binder. The method includes debinding the layers in a temperature interval of T E1 -T E3 , where T E1  is a minimum debinding temperature and T E3 &gt;T E1 , and sintering the layers at a temperature T S , where T S ≧T E3 . Debinding and sintering are performed in a same furnace, and a temperature T of the base does not fall below T E1  during debinding and sintering.

The invention relates to a method for the production of a ceramic substrate comprising a stack of layers stacked on top of one another.

Each of the layers of the stack contains a non-sintered ceramic material and binder, together forming a basic body, which is debinded and sintered.

A method is known in which, for example, the decarbonization of the basic body is performed in a batch furnace, which is heated over an extend period of time to a temperature suitable for decarbonization. Then the basic body, cooled to room temperature, is removed from the batch furnace and, together with other already decarbonized basic bodies, placed onto a conveyer belt and fed into a sintering furnace configured for conveyor belts. The use of a continuous process is feasible here, because the sintering is not as time-consuming as the decarbonization.

A disadvantage of the known method is that it is unsuitable for the production of multi-layer substrates made of various ceramic materials having different relative permittivities and generally different coefficients of thermal expansion, in which layers with feedthroughs are provided. It was discovered that during the production of such multi-layer substrates, cracks often occur between the feedthroughs, which are normally made of a metalliferous paste, and the ceramic layer forming the surrounding environment of the feedthrough.

It is, therefore, the goal of the present invention to provide a method for the production of a ceramic multi-layer substrate, in which the risk of crack development is reduced. This goal is achieved by means of method according to claim 1. Advantageous further developments of the invention are found in the additional claims.

The invention indicates a method for the production of a ceramic substrate, in which a basic body is made available in a first step. The basic body contains a stack of layers stacked on top of one another. The stacked layers each consist of a non-sintered ceramic material, which also contains a binder. The basic body contains electrically conductive vertical ducts, each of which passes through at least one of the layers. In a further step, the layers are preferably debinded in an inert atmosphere (e.g., in an atmosphere containing nitrogen), a minimum temperature being maintained during debinding. In the ensuing step, the basic body is sintered, the sintering taking place at a temperature which is greater that the minimum temperature of debinding. The minimum temperature of debinding is dependent upon the composition of the material to be debinded. Throughout the entire of the two process steps mentioned last, the temperature T of the basic body is maintained at a level that does not fall below the minimum temperature T_(E1) of the debinding.

According to the invention, both debinding and sintering are performed in one and the same furnace. This prevents the ceramic basic body from cooling to room temperature. In addition, this simplifies the method, because switching furnaces is avoided.

An advantage of the method is that it is possible to avoid cooling the basic body to room temperature between debinding and sintering. This is because cooling the basic body to room temperature between debinding and sintering holds the risk that, because of the different coefficients of thermal expansion of the electrically conductive duct and the surrounding layer, cracks can occur. As a result of the method, cooling to room temperature is avoided, also making it possible to reduce the risk of crack development. The basic body is only cooled after sintering, that is, during the stage in which the ceramic materials are already sufficiently stable, thereby reducing the risk of crack development.

Debinding is defined as a process suitable for volatilizing the organic components, especially solvents and binders, from the layers.

It is possible to perform the process steps of debinding and sintering in an air atmosphere. It is also possible to perform debinding and sintering in an inert atmosphere. Another possibility is to convert the atmosphere in the furnace during debinding in order, for example, to control the rate of oxidation of the organic components. Another possible means of controlling the rate of oxidation is a corresponding adjustment of the furnace's temperature program, in which the direction and rate of temperature change is advantageously variable. For example, the temperature can be kept constant or reduced in some time ranges, although the current temperature must always remain above the minimum temperature of debinding.

According to the invention, debinding is performed within a temperature range of T_(E1)-T_(E3) (T_(E1)<T_(E3)), wherein the temperature in one variant of the invention can be increased, essentially monotonically, from T_(E1) to T_(E3) during debinding.

In the preferred variant of the invention, the temperature is initially increased, preferably monotonically, from T_(E1) to T_(E2) (T_(E1)<T_(E2)<T_(E3)). This step is preferably performed in an inert atmosphere, wherein unwanted oxidation of the solvents and binders can be intentionally (temporarily) reduced and/or prevented.

Subsequently, the atmosphere in the furnace is converted to air atmosphere. If the furnace atmosphere is converted at relatively high temperatures>T_(E2), there is a risk that the oxidation of the organic components will occur too quickly and that the carbon dioxide developing in the process will emerge explosively from the layers. To prevent the rapid emergence of carbon dioxide from the layers, the temperature T of the basic body can be reduced, preferably concurrently with the conversion of the atmosphere or immediately thereafter, from T_(E1)≦T_(E1′)<T_(E3). Then the temperature is preferably monotonically increased to the final temperature T_(E3) of debinding.

This is followed by a further increase in the temperature to at least the value required to sinter all layers. Only after sintering is the basic body and/or the multi-layer substrate cooled to room temperature in the furnace and then removed from the furnace.

However, the cooling of the basic body to room temperature only occurs in a stage in which the stability of the ceramic layers is already sufficient to reduce the risk of development of cracks.

Between the layers, structured metallization layers are preferably provided which, like the vertical electric ducts, can be produced using a metalliferous paste.

The stack of layers stacked on top of one another is preferably a stack in which each of the layers containing ceramic material contains openings, which are filled with a metalliferous paste. The advantage of this is that the electrically conductive connections between metal layers disposed on top of one another are easily established.

The layers containing non-sintered ceramic material, which are normally also referred to as green foils, can already be provided with openings prior to formation of the stack. This can be achieved by means of punching, for example. Following the punching, the openings are filled with a metalliferous paste. Only then are the green foils stacked on top of one another and is the basic body produced by means of lamination.

A paste containing precious metals, such as silver and palladium, can be used advantageously as a metalliferous paste.

It is also advantageous if the materials of layers stacked on top of one another in the stack are different and the stack, therefore, contains at least two different ceramic materials. It is possible, for example, to use a ceramic material for a green foil disposed in the interior of the stack which has relative permittivity of approx. ε=20. This makes it possible to produce ceramic substrates that contain high-capacity capacitors. Furthermore, it is advantageous to produce the lowest and the higher layer of the stack of layers stack on top of one another by means of a ceramic material with a lower relative permittivity of, for example, ε=8.

Furthermore, it is advantageous to select the materials in accordance with the following rule:

A first ceramic material contained in the basic body begins to sinter at a temperature TsI. A second ceramic material contained in the basic body begins to sinter at a temperature TS₃. Furthermore, the metalliferous paste contained in the basic body begins to sinter at a temp T_(S2). In addition, the following applies: T_(S1)<T_(S2)<T_(S3). To obtain a densely sintered basic body, it is preferable to sinter at a temperature that exceeds the sintering temperature T_(S3).

Advantageously, the following can apply to the relative permittivity ε₁ of the ceramic material with the smaller relative permittivity: 7≦ε₁≦8.5.

In addition, the following can apply to the relative permittivity 62 of the ceramic material with the larger relative permittivity: 18≦ε₂≦22.

A structured metallization layer made of the structured metalliferous paste can be provided on the uppermost layer, below the lowest layers, and between two layers stacked on top of one another. The ducts constitute vertical electrical connections between the metallization layers.

In the following, the invention is explained in greater detail, using an exemplary embodiment and the related figures.

FIG. 1 shows, as an example, the temperature progression during completion of the method according to the invention in a chart in which the temperature is plotted over time.

FIG. 2 shows, as an example, a substrate produced by means of the method according to the invention, in schematic cross-section.

FIG. 1 shows, as an example, a temperature profile for the use of the method according to the invention to produce a ceramic substrate. One or more basic bodies are heated for a period of three hours from room temperature to a temperature T_(E1) (beginning of debinding). In the example from FIG. 1, T_(E1)=200° C. This is the level below which the temperature should not fall during the debinding. The increase in the temperature to T_(E1) can occur in an air atmosphere or, alternatively, in an inert atmosphere.

Beginning at this temperature, a large fraction of the organic components begins to escape. For this reason, the temperature is preferably increased uniformly and slowly (e.g., for approx. 13 hours), in an inert atmosphere, to a value T_(E2). During the further process, the furnace, in this variant of the invention, is converted to an air atmosphere and, in this process, the temperature is initially reduced again to a value of T_(E1)≦T<T_(E2). Without such a temperature reduction, explosion-like deflagration can occur, which can lead to damaging or destruction of the ceramic basic body.

Following the conversion of the furnace to an air atmosphere, the decarbonization process is continued. The temperature of the basic body is now increased to a temperature T_(E3), which is preferably 450° C. and is kept constant for a period of about one hour. At this point, the last organic components of the basic body also escape. Decarbonization is then complete. The ceramic basic body is subsequently heated, in a ramp-like fashion, to the sintering temperature T_(S1), at which the layers 2 of a first ceramic material begin to sinter.

A ceramic substrate in accordance with FIG. 2 is considered for the exemplary temperature profile from FIG. 1. The ceramic substrate comprises a basic body 1, which contains a stack 1 a of layers 2, 3 stacked on top of one another. The layers 2, 3 stacked on top of one another contain a non-sintered ceramic material, which, in turn, contains additional organic components such as solvents and binders. In this connection, the layers 2 are preferably executed in such a way that after sintering their relative permittivity s; is approx. 8. Another layer 3 consisting of a second ceramic material (or at least a partial layer made of the second ceramic material) is disposed between the two layers 2. The second ceramic material is a ceramic material (preferably a so-called K20 material) with a relative permittivity ε₂ that differs from ε₁. The K20 material is a ceramic material with relative permittivity ε₂ of approximately 20. In addition, vertical openings are formed in the layers and are filled with a metalliferous paste, thereby forming electrically conductive ducts 4. Internal electrodes 6 are disposed in the individual plies of the layer 3 in such a way as to form a capacitor. The capacitor is connected, in electrically conductive fashion, with an electric component 5 on the upper side of the basic body 1.

The sintering temperatures of the materials in the layers 2 and 3, and/or in the electrically conductive duct 4, are selected in such a way that the following applies to the sintering temperature T_(S1) of the ceramic material of layer 2, to the sintering temperature T_(S3) of the ceramic material of layer 3, as well as to the sintering temperature T_(S2) of the metalliferous paste: T_(S1)<T_(S2)<T_(S3). According to FIG. 1, the following applies to the temperatures:

-   -   T_(S1)=625° C.     -   T_(S3)=700° C.

From the above, it follows that after ramping up the temperature over an extended period of 40 hours, a temperature of 625° C. is reached, which is the temperature at which the first ceramic material begins to sinter. The temperature is kept constant for about 2 hours, and is then quickly increased to the value T_(S)≧T_(S3), e.g., T_(s)=900° C. This brings the temperature to a level at which the layers 2, 3 of the ceramic basic body are densely sintered. At the same time, namely during the temperature increase from T_(S1) to T_(S), the layer 3 of the second ceramic material, with a sintering temperature of T_(S3), as well as the metallic duct and the internal metal coating begin to sinter. This temperature is now held for 0.25 seconds to obtain a thickly sintered ceramic basic body.

Only after all layers and materials of the basic body are sintered is the temperature gradually reduced to room temperature if applicable FIG. 1.

At least one of the layers of the first ceramic material can form a stratified compound with at least one of the layers of the second ceramic material, wherein several of such stratified compounds are preferably formed and wherein each of the structured metallization layers is provided between the stratified compounds.

The present invention is not limited to the production of substrates that contain K8 and/or K20 materials, but instead is applicable to all types of ceramic substrates that contain feedthroughs or electrically ducts.

LIST Of Reference Symbols

-   1 Basic body -   1 a Stack -   2 Layer -   3 Layer -   4 Duct -   5 Electric component -   6 Internal electrode -   T_(E1) Minimum temperature of debinding -   T_(E2) Maximum temperature of debinding in an inert atmosphere -   T_(E3) Maximum temperature of debinding -   T_(S1) Beginning of sintering of the first ceramic layer -   T_(S2) Beginning of sintering of the metalliferous paste -   T_(S3) Beginning of sintering of the first ceramic layer -   T_(S) Sintering temperature of the basic body -   T Temperature -   t Time 

1. A method of producing a ceramic substrate comprised of a base that comprises a stack of layers, each layer in the stack comprising a non-sintered ceramic material and a binder, the method comprising: debinding the layers in a temperature interval of T_(E1)-T_(E3), where T_(E1) is a minimum debinding temperature and T_(E3)>T_(E1); and sintering the layers at a temperature T_(S), where T_(S)≧T_(E3); wherein debinding and sintering are performed in a same furnace; and wherein a temperature T of the base does not fall below T_(E1) during debinding and sintering.
 2. The method of claim 1, further comprising: forming the stack of layers; wherein forming comprises forming openings in the layers and adding a metalliferous paste to at least some of the openings.
 3. The method of claim 2, wherein the metalliferous paste comprises silver or silver-palladium.
 4. The method of claim 1, wherein at least two of the layers comprise different ceramic materials.
 5. The method of claim 2, wherein the stack of layers comprises a first layer comprised of a first ceramic material and a second layer comprised of a second ceramic material, the second layer being above the first layer; wherein the first ceramic material begins to sinter at a temperature T_(S1), the second ceramic material begins to sinter at a temperature T_(S3), wherein and the metalliferous paste begins to sinter at a temperature T_(S2); and wherein T_(S1)<T_(S2)<T_(S3).
 6. The method of claim 5, wherein, following sintering, the first ceramic material has a relative permittivity ε₁, where 7≦ε₁≦8.5; and wherein, following sintering, the second ceramic material has a relative permittivity ε₂, where 18≦ε₁≦22.
 7. The method of claim 2, wherein forming comprises providing structured metallization layers between layers in the stack comprised of sintered ceramic material, the structured metallization layers comprising the metalliferous paste.
 8. The method of claim 5, further comprising forming a stratified compound using the first layer and the second layer, the ceramic substrate comprising plural stratified compounds; and wherein forming structured metallization layers is formed between the stratified compounds.
 9. The method of claim 1, wherein debinding and sintering are performed in an inert atmosphere.
 10. The method of claim 1, wherein debinding an sintering are performed in an air atmosphere.
 11. The method of claim 1, wherein, during debinding, an atmosphere in which debinding takes place changes from an inert atmosphere to an air atmosphere during.
 12. The method of claim 11, wherein, debinding begins at a temperature between T_(E1)-T_(E2) and the temperature increases at a substantially constant rate, where T_(E1)<T_(E2)<T_(E3); whereafter, T decreases to a value of T_(E1′), where T_(E1)≦T_(E1′)<T_(E2); whereafter T increases at a substantially constant rate to a value T_(E3).
 13. The method of claim 12, wherein a first part of debinding is performed in an atmosphere that is inert; and wherein, during debinding, the atmosphere in the furnace changes to an air atmosphere in accordance with a reduction in temperature to a value of T_(E1)≦T_(E1′)<T_(E2). 